Systems and methods for image alignment

ABSTRACT

Systems and methods for image alignment are disclosed. A method includes: determining a first set of patches for a first image and a second set of patches for a second image, wherein each patch in the first and second sets of patches comprises a portion of the first and second image, respectively; determining a set of possible match pairings of a patch from the first set and a patch from the second set; for each match pairing in the set of possible match pairings, computing a transformation operation to align the patch from the first set of patches and the patch from the second set of patches in the match pairing; grouping the match pairings into clusters based on parameters of the transformation operations of the match pairings; and, performing the transformation operation corresponding to at least one cluster to align the first image to the second image.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This patent application in a continuation of U.S. non-provisionalapplication Ser. No. 14/755,897, filed on Jun. 30, 2015, which claimsthe benefit of U.S. provisional application No. 62/036,031, filed onAug. 11, 2014, both of which are hereby incorporated by reference intheir entirety.

FIELD

This disclosure relates generally to the field of image processing and,more specifically, to systems and methods for biometric image alignment.

BACKGROUND

Since its inception, biometric sensing technology, such as fingerprintsensing, has revolutionized identification and authentication processes.The ability to capture and store biometric data in a digital file ofminimal size has yielded immense benefits in fields such as lawenforcement, forensics, and information security.

Utilizing fingerprints in a biometric authentication process typicallyincludes storing one or more fingerprint images captured by afingerprint sensor as a fingerprint template for later authentication.During the authentication process, a newly acquired fingerprint image isreceived and compared to the fingerprint template to determine whetherthere is a match. Before the newly acquired fingerprint image can becompared to the fingerprint template, the newly acquired fingerprintimage is aligned by performing a transformation to the newly acquiredfingerprint image. The transformation may include one or more ofrotation, translation (in two dimensions), and scaling of the newlyacquired fingerprint image. This process is known as image alignment.

However, image alignment is a challenging problem when the newlyacquired fingerprint image and the template image are low quality or ifonly a small part of one image overlaps with a sub-part of the otherimage. With increased use of smaller image sensors, the amount ofoverlap among the images is decreasing, which further decreases theeffectiveness of conventional image alignment techniques. In addition,if a purely minutiae-based technique is used for image alignment orimage matching, the use of smaller sensors decreases the number ofminutiae points in the images, which decreases even further theeffectiveness of conventional image alignment and image matchingtechniques.

Accordingly, there remains a need in the art for systems and methods forimage alignment that address the deficiencies of conventionalapproaches.

SUMMARY

One embodiment of the disclosure provides a processing system, includinga processor and a memory storing instructions that, when executed by theprocessor, cause the processing system to compute a transformationoperation that aligns a first image to a second image. Aligning thefirst image to the second image includes: determining a first set ofpatches for the first image, wherein each of the patches in the firstset of patches comprises a portion of the first image; determining asecond set of patches for the second image, wherein each of the patchesin the second set of patches comprises a portion of the second image;for each of the patches in the first and second sets of patches,computing a value of an attribute of the patch, wherein the attribute isinvariant to the transformation operation; discarding one or more patchpairings including a patch from the first set of patches and a patchfrom the second set of patches in response to determining that therotation-invariant attributes do not match for the patch pairing; forone or more patch pairings that are not discarded, identifying asimilarity value between the patch from the first set of patches and thepatch from the second set of patches in the patch pairing; selecting aset of candidate pairings based on identifying the patch pairings havinga similarity value that satisfies a threshold; for each candidatepairing in the set of candidate pairings, determining a transformationoperation to align the patch from the first set of patches and the patchfrom the second set of patches in the candidate pairing; grouping thecandidate pairings into clusters based on parameters of thetransformation operations of the candidate pairings; and performing thetransformation operation corresponding to at least one of the clustersto align the first image to the second image.

Another embodiment of the disclosure provides a method, comprising:determining a first set of patches for a first image, wherein each patchin the first set of patches comprises a portion of the first image;determining a second set of patches for a second image, wherein eachpatch in the second set of patches comprises a portion of the secondimage; determining a set of possible match pairings of a patch from thefirst set of patches and a patch from the second set of patches; foreach match pairing in the set of possible match pairings, computing atransformation operation to align the patch from the first set ofpatches and the patch from the second set of patches in the matchpairing; grouping the match pairings into clusters based on parametersof the transformation operations of the match pairings; and, performingthe transformation operation corresponding to at least one cluster toalign the first image to the second image.

Yet another embodiment of the disclosure provides an electronic device,comprising: a fingerprint sensor configured to capture a first image ofa fingerprint; a memory storing a second image of a fingerprint; and aprocessor. The processor is configured to perform the steps of:determining a first set of patches for a first image, wherein each patchin the first set of patches comprises a portion of the first image;determining a second set of patches for a second image, wherein eachpatch in the second set of patches comprises a portion of the secondimage; determining a set of possible match pairings of a patch from thefirst set of patches and a patch from the second set of patches; foreach match pairing in the set of possible match pairings, computing atransformation operation to align the patch from the first set ofpatches and the patch from the second set of patches in the matchpairing; grouping the match pairings into clusters based on parametersof the transformation operations of the match pairings; performing thetransformation operation corresponding to at least one cluster to alignthe first image to the second image; and determining whether the alignedfirst image is a fingerprint match to the second image.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an example electronic system that includesan input device and a processing system, according to an embodiment ofthe disclosure.

FIG. 2A illustrates a grayscale fingerprint image that shows variousridges and minutiae of a fingerprint, according to one embodiment.

FIG. 2B illustrates a skeletonized version of the grayscale fingerprintimage in FIG. 2A, according to one embodiment.

FIG. 3A illustrates a small grayscale fingerprint image that showsvarious ridges and minutiae of a fingerprint, according to oneembodiment.

FIG. 3B illustrates a skeletonized version of the grayscale fingerprintimage in FIG. 3A, according to one embodiment.

FIG. 4 is a flow diagram of method steps for aligning two images,according to one embodiment of the disclosure.

FIG. 5 is a flow diagram of method steps of determines a set of possiblematch pairings between patches in a first image and patches in a secondimage, according to one embodiment of the disclosure.

FIGS. 6A-6B are examples of skeletonized fingerprint images withcircular patches shown thereon, according to some example embodiments.

FIG. 7 is a diagram of a patch showing local curvature vectors and anaverage curvature of the patch, according to one embodiment.

DETAILED DESCRIPTION

Some embodiments of the disclosure address the problem of imagealignment for images having significant oriented texture or edges.Fingerprint images are examples of such images; however, iris images,vein patterns, and aerial views of a city are other examples. Asdescribed, image alignment is a challenging problem when images are lowquality or if only a small part of one image overlaps with a sub-part ofanother image, as is common when the images are captured using verysmall sensors.

In conventional approaches to fingerprint matching, minutiae points aredetected in the images. The locations and corresponding orientations ofthe minutia points form the features of interest for each image beingcompared. The sets of minutia from the two images are aligned to oneanother using a voting procedure in Hough space based on each possiblepoint-to-point correspondence between the two minutia sets, and theminutia points in the aligned minutia sets are compared to each other todetermine whether they are a match. Unfortunately, these conventionalfingerprint matching techniques rely on large numbers of minutia pointsto be present in the images, both for the alignment stage, as well asfor the matching stage where the aligned images are compared todetermine whether they were derived from the same user fingerprint. Theuse of smaller sensors decreases the number of minutiae points in theimages, which decreases the effectiveness of these conventional imagealignment and image matching techniques.

Embodiments of the disclosure provide image alignment techniques thatcan operate on small images with few or even no minutiae points in theoverlap area of the two images. In some embodiments, each image isdivided into small regions, also referred to herein as “patches.”Certain features are computed for each patch in the two images. Someexamples of features that may be computed for each patch include: (a) anumber of edge points in the patch, (b) a rotation-invariant moment ofthe patch, such as the Hu moment, (c) an average curvature of the edgesin the patch, (d) a dominant orientation of the edges in the patch, ifany, (e) an edge pixel density for the patch, (f) an edge map for thepatch, or (g) a distance map computed from the edge map for the patch.

Suppose one wishes to align a first image and a second image. Nowsuppose that the first image is divided into N patches and the secondimage is divided into M patches. Each patch may be a circular regiontaken from the given image. The patches may overlap one another within agiven image. In this example, there is a total of N×M patch matchhypotheses for matching the first image to the second image.

The patch match hypotheses can then be evaluated to select a set ofpossible match pairings. This may be based on similarity betweenfeatures of the patches from the different images. A large number ofthese patch match hypotheses can be discarded quickly by comparing oneor more of the attributes computed for the patches. The attributes usedto quickly discard pairings of the patches may be invariant to thetransformation being computed to align the patches (e.g., invariant totranslation, rotation, or scaling). For example, if a rotationaltransformation is being computed to align the images, rotation invariantattributes such as the number of edge points and the rotation-invariantHu moments can be used to discard a patch pairing as a possible patchmatch; if a scale factor is being computed, scale invariant attributessuch as the edge pixel density can be used to discard a patch pairing asa possible patch match. If the attributes, such as the number of edgepoints and the rotation-invariant Hu moments, do not match for a givenpairing of patches (e.g., one patch from each image in the pairing ofpatches), that particular pairing of patches can be discarded as apossible patch match.

For each of X pairings of patches that remain following culling of someof the patch match hypotheses, a transformation is computed that alignsthe patch in the pairing from the first image to the patch in pairingfrom the second image. The transformation may include an x-translation,a y-translation, and a rotation. In some implementations, thetransformation may further include a scale factor.

In some embodiments, the X transformations corresponding to the Xpairings of patches are clustered into K clusters according tosimilarities between the transformations. The transformationscorresponding to the top clusters may be selected as possibletransformations that align the first image to the second image. Thetransformations corresponding to these top clusters may then be testedon the images as transformation hypotheses to attempt to align theimages. If after applying one of the transformations to the first imageresults in a match to the second image, then a positive match isidentified between the first and second image. If however none of thetransformations corresponding to the top clusters results in a match, itmay be determined that the first image does not match the second image.

FIG. 1 is a block diagram of an example electronic system 100 thatincludes an input device 102 and a processing system 104, according toan embodiment of the disclosure. The basic functional components of theelectronic device 100 utilized during capturing, storing, and validatinga biometric authentication attempt are illustrated. The processingsystem 104 includes a processor(s) 106, a memory 108, a template storage110, an operating system (OS) 112, and a power source(s) 114. Each ofthe processor(s) 106, the memory 108, the template storage 110, theoperating system 112 and power source 114 are interconnected physically,communicatively, and/or operatively for inter-component communications.

As illustrated, processor(s) 106 are configured to implementfunctionality and/or process instructions for execution withinelectronic device 100 and the processing system 104. For example,processor 106 executes instructions stored in memory 108 or instructionsstored on template storage 110 to determine whether a biometricauthentication attempt is successful or unsuccessful. Memory 108, whichmay be a non-transitory, computer-readable storage medium, is configuredto store information within electronic device 100 during operation. Insome embodiments, memory 108 includes a temporary memory, an area forinformation not to be maintained when the electronic device 100 isturned off. Examples of such temporary memory include volatile memoriessuch as random access memories (RAM), dynamic random access memories(DRAM), and static random access memories (SRAM). Memory 108 alsomaintains program instructions for execution by the processor 106.

Template storage 110 comprises one or more non-transitorycomputer-readable storage media. In the context of a fingerprint sensor,the template storage 110 is generally configured to store enrollmentviews for fingerprint images for a user's fingerprint or otherenrollment information. The template storage 110 may further beconfigured for long-term storage of information. In some examples, thetemplate storage 110 includes non-volatile storage elements.Non-limiting examples of non-volatile storage elements include magnetichard discs, optical discs, floppy discs, flash memories, or forms ofelectrically programmable memories (EPROM) or electrically erasable andprogrammable (EEPROM) memories, among others.

The processing system 104 also hosts an operating system (OS) 112. Theoperating system 112 controls operations of the components of theprocessing system 104. For example, the operating system 112 facilitatesthe interaction of the processor(s) 106, memory 108 and template storage110. According to various embodiments, the processor(s) 106 implementhardware and/or software to align two images and compare the alignedimages to one another to determine whether there is a match, asdescribed in greater detail below.

The processing system 104 includes one or more power sources 114 toprovide power to the electronic device 100. Non-limiting examples ofpower source 114 include single-use power sources, rechargeable powersources, and/or power sources developed from nickel-cadmium,lithium-ion, or other suitable material.

Input device 102 can be implemented as a physical part of the electronicsystem 100, or can be physically separate from the electronic system100. As appropriate, the input device 102 may communicate with parts ofthe electronic system 100 using any one or more of the following: buses,networks, and other wired or wireless interconnections. In someembodiments, input device 102 is implemented as a fingerprint sensor andutilizes one or more various electronic fingerprint sensing methods,techniques, and devices to capture a fingerprint image of a user. Inputdevice 102 may utilize any type of technology to capture a biometriccorresponding to a user. For example, in certain embodiments, the inputdevice 102 may be an optical, capacitive, thermal, pressure, radiofrequency (RF) or ultrasonic sensor.

Some non-limiting examples of electronic systems 100 include personalcomputers of all sizes and shapes, such as desktop computers, laptopcomputers, netbook computers, tablets, web browsers, e-book readers, andpersonal digital assistants (PDAs). Additional example electronicsystems 100 include composite input devices, such as physical keyboardsand separate joysticks or key switches. Further example electronicsystems 100 include peripherals such as data input devices (includingremote controls and mice) and data output devices (including displayscreens and printers). Other examples include remote terminals, kiosks,video game machines (e.g., video game consoles, portable gaming devices,and the like), communication devices (including cellular phones, such assmart phones), and media devices (including recorders, editors, andplayers such as televisions, set-top boxes, music players, digital photoframes, and digital cameras).

As described in greater detail herein, embodiments of the disclosureprovide systems and methods to match a newly acquired image with atemplate image, such as in the context of fingerprint matching. As partof the image matching process, the newly acquired image is first alignedto the template image.

FIG. 2A illustrates a grayscale fingerprint image that shows variousridges and minutiae of a fingerprint, according to one embodiment. Ascan be seen in FIG. 2A, the image is noisy such that portions of theimage are cloudy and the ridges or contours are broken. FIG. 2Billustrates a skeletonized version of the grayscale fingerprint image inFIG. 2A, according to one embodiment. Fingerprint skeletonization, alsoreferred to as thinning, is the process of converting the ridge lines ina grayscale fingerprint image (see, for example, the image in FIG. 2A)to a binary representation, and reducing the width of binarized ridgelines to one pixel wide. As can be seen in FIG. 2B, the skeletonizedversion of the grayscale fingerprint image removes much of the noise sothat the image is no longer cloudy and the ridge lines are no longerbroken.

FIG. 3A illustrates a small grayscale fingerprint image that showsvarious ridges and minutiae of a fingerprint, according to oneembodiment. As can be seen in FIG. 3A, the image is noisy such thatportions of the image are cloudy and the ridges or contours are broken.Also, the image in FIG. 3A is much smaller than the image shown in FIG.2A. This may be a result of, for example, using a smaller sensor tocapture the image in FIG. 3A. FIG. 3B illustrates a skeletonized versionof the grayscale fingerprint image in FIG. 3A, according to oneembodiment.

FIG. 4 is a flow diagram of a method 400 for aligning two images,according to one embodiment of the disclosure. At step 402, a processingsystem receives a first image. At step 404, the processing systemreceives a second image. In some embodiments, the first image is a newlyacquired image captured by an image sensor, and the second image is atemplate image that was previously acquired to which the first image isto be compared to determine whether there is a match.

In some embodiments, each of the first and second images areskeletonized images. As such, appropriate pre-processing (not shown) maybe performed to convert a grayscale image, such as a fingerprint image,to a skeletonized image (also sometimes referred to herein as an “edgemap,” “edge image,” or “thinned ridge image,” depending on the context).In some embodiments, converting the second image (i.e., template image)to a skeletonized format is pre-computed by the processing system onceand does not need to be recomputed each time that a newly acquired imageis presented to compare to the second image.

At step 406, the processing system divides the first image into Npatches. As described, each patch may be a circular region of the firstimage. The patches in the first image may overlap one another. At step408, the processing system divides the second image into M patches. Asdescribed, each patch may be a circular region of the second image. Thepatches in the second image may overlap one another. In someembodiments, N=M. In other embodiments, N and M are not equal, such aswhen the first and second images are of different sizes.

Although steps 402 and 406 are shown to be performed in parallel withsteps 404 and 408, in other embodiments, steps 402, 404, 406, 408 can beperformed serially or in any technically feasible order.

FIGS. 6A-6B are examples of skeletonized fingerprint images withcircular patches 602 shown thereon, according to some exampleembodiments. In one example, the image in FIG. 6A corresponds to thefirst image and the image in FIG. 6B corresponds to the second image.According to some embodiments, the entirety of the images are covered inpatches. In FIGS. 6A-6B, however, only a portion of the patches areshown for clarity.

Referring back to FIG. 4, at step 410, the processing system determinesa set of possible match pairings between patches in a first image andpatches in a second image. An example embodiment for performing step 410is shown in FIG. 5 with additional detail.

FIG. 5 is a flow diagram of method steps of determines a set of possiblematch pairings between patches in a first image and patches in a secondimage, according to one embodiment of the disclosure. At step 504, theprocessing system receives the N patches corresponding to the firstimage (see, step 406 in FIG. 4) and computes various properties of eachpatch, also referred to herein as “features.” Some examples of featuresthat are computed for each patch include: (a) a number of edge points inthe patch, (b) a rotation-invariant moment of the patch, such as the Humoment, (c) an average curvature of the edges in the patch, (d) adominant orientation of the edges in the patch, if any, (e) an edgepixel density for the patch, or (f) an edge map for the patch, or (g) adistance map computed from the edge map for the patch.

At step 506, the processing system receives the M patches correspondingto the second image (see, step 408 in FIG. 4) and computes variousproperties of each patch, also referred to herein as “features.” In oneembodiment, the same properties of each patch in the second image arecomputed as for the first image. In addition, although steps 504 and 506are shown to be performed in parallel, in other embodiments, steps 504and 506 can be performed serially or in any technically feasible order.In some embodiments, 504 and 506 are omitted, and each particularproperty of the patches in the first and second images is computedon-demand during the remaining steps in FIG. 5, as described in greaterdetail below.

At step 508, the processing system determines, for each pairing ofpatches (p_(i), q_(k)) whether the pairing of patches has the samenumber of edge points, where p_(i) is one of the N patches in the firstimage and q_(k) is one of the M patches in the second image. A pairingof patches may be considered to have the same number of edge points whenthe ridge pixel counts are within a tolerance threshold.

As shown at step 510, if, for a given pairing of patches, the processingsystem determines that the pairing of patches does not have the samenumber of edge points, then the pairing of patches is discarded aspossible match pairing.

If a pairing of patches satisfies the criterion at step 508 (i.e., thateach patch in the pairing of patches has the same number of edge pointswithin a tolerance), then at step 512, the processing system determines,for each pairing of patches (p_(i), q_(k)) that passed step 508, whethereach patch in the pairing of patches has the same rotation-invariantmoment, such as the “Hu” moment. An image moment is a certain particularweighted average of the intensities of the pixels in the image, or afunction of such weighted average. A pairing of patches may beconsidered to have the same rotation-invariant moment when the valuesare within a tolerance threshold.

As shown at step 514, if, for a given pairing of patches, the processingsystem determines that the pairing of patches does not have the samerotation-invariant moment, then the pairing of patches is discarded aspossible match pairing.

If a pairing of patches satisfies the criterion at step 512 (i.e., thatthe patches in the pairing of patches have the same rotation-invariantmoment), then at step 516, the processing system determines, for eachpairing of patches (p_(i), q_(k)) that passed step 512, whether eachpatch in the pairing of patches has the same average curvature. Ifrotation is one of the parameters being computed for the transformationthat aligns the two images, then the curvature attribute used at thisstage may be computed without regard to directionality. This allowspatch pairings to be discarded where a degree of curvature in the twopatches differs beyond a tolerance value.

FIG. 7 is a diagram of a patch showing local curvature vectors and anaverage curvature of the patch, according to one embodiment. As shown inFIG. 7, a circular patch 702 of a fingerprint image includes one or moreridges 708. Each ridge 708 is associated with some curvature. The ridges708 tend to be very nearly parallel with neighboring ridges locally, butcan curve along their length. Within a patch 702, the average curvatureor set of curvatures can be used to locate a focus 706. When searchingfor patches in a second image that match a give patch in a first image,the average curvature, set of curvatures, or focus 706 may be computedfor each patch and used to guide the alignment between those patches.

Referring back to FIG. 5, as shown at step 518, if, for a given pairingof patches, the processing system determines that each patch in thepairing of patches does not have the same average curvature, then thepairing of patches is discarded as possible match pairing. The curvatureof the patch at this stage may be used as a rotation-invariant attributefor the patch without regard to the directionality of the curvature.

If a pairing of patches satisfies the criterion at step 516 (i.e., thateach patch in the pairing of patches has the same average curvature),then remaining pairings of patches can be aligned, and similaritybetween the patches in the pairings can be evaluated more closely forsimilarity. At step 520, the processing system determines, for eachpairing of patches (p_(i), q_(k)) that passed step 516, whether eachpatch in the pairing of patches has a dominant orientation. A givenpatch may be considered to have a dominant orientation if a certainpercentage of the ridges in the patch have approximately the samedirectionality. If both patches in a given pairing have a dominantorientation (say, t₁ and t₂, respectively), then at step 522, theprocessing system steers the first patch in the pairing to match thedominant orientation of the second patch in the pairing. For example,the first patch may be rotated by t₂−t₁ degrees. If one or both of thepatches in the pairing of patches does not have a dominant orientation,then at step 524, the processing system rotates the first patch in smallincrements covering the range of possible rotational transformationsbeing searched (e.g., covering 360 degrees) to find the angle that givesthe best match to the second patch.

Referring to FIG. 7, in some embodiments, for each ridge 708 in a patch702, a local radius vector 704 is computed. The directionality of thelocal radius vector 704 is based on the curvature of the ridge 708,where an end point of the local radius vector 704 is the point thatwould be the center of a circle crated by extending the ridge 708. Thefocus 706 of the patch 702 is computed by calculating an average of theend points of the local radius vectors 704. Aligning the dominantdirection of the ridges in a pairing of patches gives a firstapproximation of the angular alignment between the two patches. Thatalignment allows two possible angles, differing by 180 degrees.Alignment between two patches can be guided by the approximating thatthey have a similar focus. This may allow two possible angles determinedbased on dominant direction to be disambiguated based on directionalityof the curvature. This also allows steering the translational adjustmentof the alignment between two patches. In another embodiment, steeringmay simply be guided based on the curvature of the patches instead ofthe dominant orientation.

From steps 522 and 524, the method in FIG. 5 proceeds to step 526, wherethe processing system computes a similarity score between the rotatedfirst patch and the second patch. In one embodiment, computing thesimilarity score may comprise computing a chamfer distance between therotated first patch and the second patch. Calculating a chamfer distancecomprises computing a measure of dissimilarity between two images. Ingeneral, to compute a chamfer distance, the processing system extractsthe edge/contours of a query image as well as the edge/contours of atarget image, takes one point/pixel of contour in the query image andfinds a distance of a closest point/pixel of contour in target image,and computes a sum the distances for all edge points/pixels of queryimage. In other embodiments, different similarity metrics may be used tocompute the similarity score. For example, different features of thepatches, such as the distance map, may be used.

At step 528, the processing system selects the pairings of patches thathave a similarity score that satisfies a threshold as the possible matchpairings. The patches can be considered to have a similarity score thatsatisfies a threshold when a matching score between the aligned patchesis above a threshold, or when a difference score between the alignedpatches is below a threshold. For example, if chamfer distance betweenedge maps for the patches is used as the similarity metric, thesimilarity score may be satisfied if the chamfer distance is below acertain threshold.

In some embodiments, it is possible to select two or more patches withinan image for computation of the similarity of between pairings ofpatches at step 526. In these embodiments, instead of a pairing (p_(i),q_(k)) of a single patch in the first image with a single patch in thesecond image, the pairing involves pairing a set of multiple patches inthe first image with a set of multiple patches in the second image,e.g., (p_(i), p_(j); q_(k), q_(h)). The number of patches in each setmay also be associated with the number of transformation parametersbeing computed to resolve the patch pairing alignment for computation ofthe similarity score. For example, instead of incrementally steering thepatch in the first image, or using the dominant orientation to steer thepatch in the first image, multiple patches can be selected from thefirst image with their geometric relationship to each other preserved. Atransformation involving translation, rotation, and scaling of thepatches from the first set can be resolved by selecting two patches inthe first image and computing the translation and rotation that alignsthis to a set of two patches from the second image. Similarly, three ormore patches from the first image can be paired with a similar number ofpatches from the second image to compute a more complex transformationor provide a more accurate result. For example, three patches may besufficient to resolve a more complex affine transformation.

Also, it should be noted that although certain criteria (i.e.,attributes) are used to cull certain patch pairings as possible matchesat steps 508, 512, 516, these culling steps can be performed in anyother order. In other embodiments, different or additional cullingparameters may be utilized to discard certain pairings of patches aspossible matches.

Referring back to FIG. 4, as described above, at step 410 the processingsystem determines the set of possible match pairings. At step 412, theprocessing system computes, for each possible match pairing, atransformation T_(ij) that transforms the first patch to the secondpatch. The transformation can be characterized by an x-translation, ay-translation, and a rotation. In some embodiments, a scale factor mayalso be included as a transformation parameter.

At step 414, the processing system clusters the possible match pairingsinto K buckets based on the transformation values. If a transformationhas values for its x-translation, y-translation, rotation that arewithin certain thresholds of the x-translation, y-translation, rotationof another transformation, respectively, then those two transformationscan be clustered into the same bucket. At step 416, the processingsystem sorts the K buckets by count. At step 418, the processing systemselects the top L buckets as possible buckets for transformations thatalign the first image to the second image.

Each of the top L buckets is then analyzed to determine whether thebucket corresponds to a transformation that aligns the first image tothe second image. For a given bucket, the processing system inspects thepatches that are included the bucket. The processing system counts thenumber of edge points that fall within the patches in which the discsare inscribed. Let the number of edge points that fall within thepatches be Y. Next, the processing system counts the number of edgepoints in the overlap region (between the first image and the secondimage, as per the transformation hypothesis corresponding to the bucket)that are not covered by the Y patches. Let this number be Z. The patchmatch score Scan be computed as S=Y−a·Z, where “a” is typically a numbergreater than 1. In other words, the processing system penalizes no edgematches in the overlap region more than it rewards edge matches. Thebucket receiving the highest score is chosen for further analysis. Thescore as defined above serves as the matching score between the twoimages. The overall transformation between the two images can becomputed using the RANSAC algorithm, starting from the patch matchescontributing to this cluster. Once the first image is aligned with thesecond image, the processing system can perform an analysis to determinewhether the first image matches the second image, such as whether thereis a biometric match, such as a fingerprint match or vein pattern match.

Advantageously, embodiments of the disclosure provide an image alignmenttechnique that can operate on relatively small images, such as thosethat have no minutiae points in common.

The embodiments and examples set forth herein were presented in order tobest explain the present disclosure and its particular application andto thereby enable those skilled in the art to make and use theinvention. However, those skilled in the art will recognize that theforegoing description and examples have been presented for the purposesof illustration and example only. The description as set forth is notintended to be exhaustive or to limit the invention to the precise formdisclosed.

All references, including publications, patent applications, andpatents, cited herein are hereby incorporated by reference to the sameextent as if each reference were individually and specifically indicatedto be incorporated by reference and were set forth in its entiretyherein.

The use of the terms “a” and “an” and “the” and “at least one” andsimilar referents in the context of describing the invention (especiallyin the context of the following claims) are to be construed to coverboth the singular and the plural, unless otherwise indicated herein orclearly contradicted by context. The use of the term “at least one”followed by a list of one or more items (for example, “at least one of Aand B”) is to be construed to mean one item selected from the listeditems (A or B) or any combination of two or more of the listed items (Aand B), unless otherwise indicated herein or clearly contradicted bycontext. The terms “comprising,” “having,” “including,” and “containing”are to be construed as open-ended terms (i.e., meaning “including, butnot limited to,”) unless otherwise noted. Recitation of ranges of valuesherein are merely intended to serve as a shorthand method of referringindividually to each separate value falling within the range, unlessotherwise indicated herein, and each separate value is incorporated intothe specification as if it were individually recited herein. All methodsdescribed herein can be performed in any suitable order unless otherwiseindicated herein or otherwise clearly contradicted by context. The useof any and all examples, or exemplary language (e.g., “such as”)provided herein, is intended merely to better illuminate the inventionand does not pose a limitation on the scope of the invention unlessotherwise claimed. No language in the specification should be construedas indicating any non-claimed element as essential to the practice ofthe invention.

Preferred embodiments of this invention are described herein, includingthe best mode known to the inventors for carrying out the invention.Variations of those preferred embodiments may become apparent to thoseof ordinary skill in the art upon reading the foregoing description. Theinventors expect skilled artisans to employ such variations asappropriate, and the inventors intend for the invention to be practicedotherwise than as specifically described herein. Accordingly, thisinvention includes all modifications and equivalents of the subjectmatter recited in the claims appended hereto as permitted by applicablelaw. Moreover, any combination of the above-described elements in allpossible variations thereof is encompassed by the invention unlessotherwise indicated herein or otherwise clearly contradicted by context.

1. (canceled)
 2. A processing system, comprising: a processor; and amemory storing instructions that, when executed by the processor, causethe processing system to align a first biometric image to a secondbiometric image, the processor being configured to: determine a firstset of patches for the first biometric image, wherein each of thepatches in the first set of patches comprises a portion of the firstbiometric image; determine a second set of patches for the secondbiometric image, wherein each of the patches in the second set ofpatches comprises a portion of the second biometric image; for each ofthe patches in the first and second sets of patches, compute a value ofa rotation-invariant feature of the patch; determine a plurality ofpatch match pairings based on values of the rotation-invariant feature,wherein each of the patch match pairings comprises a pairing of a patchin the first set of patches with a patch in the second set of patches;determine a transformation operation that aligns a grouping of patchesin the first set of patches with a grouping of patches in the second setof patches, wherein the grouping of patches in the first set of patchesand the grouping of patches in the second set of patches are selectedfrom the plurality of patch match pairings; and perform thetransformation operation to align the first biometric image to thesecond biometric image.
 3. The processing system of claim 2, whereindetermining the plurality of patch match pairings comprises: comparing avalue of the rotation invariant feature of a first patch in the firstset of patches with a value of the rotation invariant feature of asecond patch in the second set of patches; determining that a similaritybetween the value of the rotation invariant feature of the first patchand the value of the rotation invariant feature of the second patchsatisfies a threshold; and identifying a pairing of the first patch withthe second patch as one of the plurality of patch match pairings.
 4. Theprocessing system of claim 2, wherein determining the transformationoperation comprises: computing a translation and rotation that alignsthe grouping of patches in the first set of patches with the grouping ofpatches in the second set of patches when a geometric relationshipbetween patches in the grouping of patches in the first set of patchesis preserved.
 5. The processing system of claim 2, the processor beingfurther configured to: determine an orientation of a given patch in thefirst set of patches; and steer the given patch based on theorientation.
 6. The processing system of claim 2, the processor beingfurther configured to: determine a dominant direction of a given patchin the first set of patches, wherein the dominant direction correspondsto directionality of multiple ridges in the given patch.
 7. Theprocessing system of claim 2, wherein each patch in the first set ofpatches has a circular shape.
 8. The processing system of claim 2,wherein performing the transformation operation includes performing atranslation and a rotation.
 9. The processing system of claim 2, whereinat least two patches in the first set of patches at least partiallyoverlap one another.
 10. The processing system of claim 2, wherein,after the first biometric image is aligned to the second biometricimage, the processor is further configured to: determine whether thefirst biometric image is a fingerprint match to the second biometricimage.
 11. A method comprising: determining a first set of patches for afirst biometric image, wherein each of the patches in the first set ofpatches comprises a portion of the first biometric image; determining asecond set of patches for a second biometric image, wherein each of thepatches in the second set of patches comprises a portion of the secondbiometric image; for each of the patches in the first and second sets ofpatches, computing a value of a rotation-invariant feature of the patch;determining a plurality of patch match pairings based on values of therotation-invariant feature, wherein each of the patch match pairingscomprises a pairing of a patch in the first set of patches with a patchin the second set of patches; determining a transformation operationthat aligns a grouping of patches in the first set of patches with agrouping of patches in the second set of patches, wherein the groupingof patches in the first set of patches and the grouping of patches inthe second set of patches are selected from the plurality of patch matchpairings; and performing the transformation operation to align the firstbiometric image to the second biometric image.
 12. The method of claim11, wherein determining the plurality of patch match pairings comprises:comparing a value of the rotation invariant feature of a first patch inthe first set of patches with a value of the rotation invariant featureof a second patch in the second set of patches; determining that asimilarity between the value of the rotation invariant feature of thefirst patch and the value of the rotation invariant feature of thesecond patch satisfies a threshold; and identifying a pairing of thefirst patch with the second patch as one of the plurality of patch matchpairings.
 13. The method of claim 11, wherein determining thetransformation operation comprises: computing a translation and rotationthat aligns the grouping of patches in the first set of patches with thegrouping of patches in the second set of patches when a geometricrelationship between patches in the grouping of patches in the first setof patches is preserved.
 14. The method of claim 11, further comprising:determining an orientation of a given patch in the first set of patches;and steering the given patch based on the orientation.
 15. The method ofclaim 11, further comprising: determining a dominant direction of agiven patch in the first set of patches, wherein the dominant directioncorresponds to directionality of multiple ridges in the given patch. 16.The method of claim 11, wherein performing the transformation operationincludes performing a translation and a rotation.
 17. The method ofclaim 11, wherein at least two patches in the first set of patches atleast partially overlap one another.
 18. A non-transitorycomputer-readable storage medium storing instructions that, whenexecuted by a processor, cause a computer system to align a firstbiometric image to a second biometric image, by performing the steps of:determine a first set of patches for the first biometric image, whereineach of the patches in the first set of patches comprises a portion ofthe first biometric image; determine a second set of patches for thesecond biometric image, wherein each of the patches in the second set ofpatches comprises a portion of the second biometric image; for each ofthe patches in the first and second sets of patches, compute a value ofa rotation-invariant feature of the patch; determine a plurality ofpatch match pairings based on values of the rotation-invariant feature,wherein each of the patch match pairings comprises a pairing of a patchin the first set of patches with a patch in the second set of patches;determine a transformation operation that aligns a grouping of patchesin the first set of patches with a grouping of patches in the second setof patches, wherein the grouping of patches in the first set of patchesand the grouping of patches in the second set of patches are selectedfrom the plurality of patch match pairings; and perform thetransformation operation to align the first biometric image to thesecond biometric image.
 19. The computer-readable storage medium ofclaim 18, wherein determining the plurality of patch match pairingscomprises: comparing a value of the rotation invariant feature of afirst patch in the first set of patches with a value of the rotationinvariant feature of a second patch in the second set of patches;determining that a similarity between the value of the rotationinvariant feature of the first patch and the value of the rotationinvariant feature of the second patch satisfies a threshold; andidentifying a pairing of the first patch with the second patch as one ofthe plurality of patch match pairings.
 20. The computer-readable storagemedium of claim 18, wherein determining the transformation operationcomprises: computing a translation and rotation that aligns the groupingof patches in the first set of patches with the grouping of patches inthe second set of patches when a geometric relationship between patchesin the grouping of patches in the first set of patches is preserved. 21.The computer-readable storage medium of claim 18, wherein executing theinstructions further causes the computer system to: determine anorientation of a given patch in the first set of patches; and steer thegiven patch based on the orientation.